Apparatus for executing an application function using a mail link and methods therefor

ABSTRACT

A method for effecting the execution of an application function on an application server from a client device via a proxy server, including transmitting a first text message pertaining to a request to execute the application function to the proxy server. The method additionally includes authenticating a user associated with the first text message by authenticating the user via a confirmation address that is different from the text message origination address. After authentication, the method also includes executing the application function at the application server as specified by the first text message, whereby the first application function is ascertained based at least on the text message destination address.

RELATED APPLICATIONS

This application is a continuation-in-part of a commonly-owned U.S. application Ser. No. 11/280,140, entitled “ARCHITECTURE FOR GENERAL PURPOSE TRUSTED PERSONAL ACCESS SYSTEM AND METHODS THEREFOR” filed on Nov. 15, 2005, which claims priority under 35 U.S.C. §119(e) of a U.S. provisional application Ser. No. 60/633,327 filed on Dec. 3, 2004 and entitled “ARCHITECTURE FOR GENERAL PURPOSE TRUSTED PERSONAL ACCESS SYSTEM AND METHODS THEREFOR.”

BACKGROUND OF THE INVENTION

The present invention relates in general to personal communication systems. More particularly, the present invention relates to methods and apparatus for executing an application function across a network.

The mobile nature of today's workforce makes it often difficult to securely take advantage of internal network resources and applications when workers are away from their desks. One common communication technique may be email. Used throughout the enterprise and across organizational boundaries, email is used to communicate and request information or action.

Much like the telephone for voice communication, email has been adopted as a primary application for business, in particular for both remote and mobile access. In the enterprise, email tends to be the primary business communication platform and, hence, is almost always open on a user's desktop. It also tends to be the primary application for wireless users.

Email was originally developed as an electronic extension to regular physical mail, and as such is principally asynchronous and freeform. Asynchronous generally means that a process (e.g., sending an email) operates independently of other processes (e.g. receiving an email), whereas synchronous means that the process runs only as a result of some other process being completed or handing off operation (e.g., voice telephone conversation). An email message is generally composed by a first user, and sent to a second user, where it is queued in the second user's inbox to be subsequently read and possibly responded to at a later time. Freeform refers to the relatively small amount of standardized information in an email message. That is, aside from a few fixed fields (e.g., destination address, origin address, and subject etc.), the majority of the email document itself comprises the content or body. This is comparable to a physical mail message which generally only requires the destination address.

The person-to-person nature of email generally makes it not useful for access network resources (e.g., databases, sales tools, etc.) that require more sophisticated client applications with more robust user interfaces, such as a web browser. That is, errors are generally indicated by human readable text that is relatively freeform and not standardized, making it hard for program to program communication. In addition, many mobile wireless devices (e.g., cell phone, PDA, etc.) are relatively small, and hence problematic for the remote access of internal network resources. Current enterprise software platforms were not originally deployed for this type of access, and so often require significant development, implementation and management expenditures to support access from these wireless devices.

Mobile devices generally present the user with a relatively poor user interface for applications other than voice, because of both battery duration and form-factor requirements. Although receiving messages is easy, with the exception of voice, small displays and keyboards make transmitting messages awkward and problematic. For example, sending a text message may take a substantial effort because of the relatively small size mobile keyboards. In addition, devices without full keyboards (such as the numeric keypads on most cell phones) practically restrict data transmission to short messages (e.g., SMS, etc.).

Screen size also tends to limit the use of conventional client/server applications and browsers. Existing applications and web-sites generally do not work with the small screens on mobile devices despite attempts at screen panning or automatic conversion from HTML to WML. Some vendors have chosen to write new versions of their applications or web-sites especially for the mobile worker but this is non-trivial (one screen must become many mobile-screens) and therefore expensive to implement. Also, there is a lack of portability standards for mobile software and given the variety and rapid development of devices at the present time we should not expect to see this situation improve soon.

In view of the foregoing, there is desired an architecture for general purpose trusted personal access system and methods therefor.

SUMMARY OF THE INVENTION

The invention relates, in an embodiment to a method for effecting the execution of an application function on an application server from a client device. The client device is coupled to a proxy server, the proxy server being further coupled to the application server that executes an application implementing the application function. The method includes selecting a request to execute the application function from a set of application function requests on the client device. The method further includes transmitting a first text message pertaining to the request to the proxy server, the first text message including a text message destination address and a text message origination address, the first text message pertaining to a request to execute the application function. The method additionally includes authenticating a user associated with the first text message origination address by sending an authentication message to the user at a text message confirmation address that is different from the text message origination address and receiving confirmation from the user responsive to the authentication message. If the user is authenticated by the authenticating, the method also includes executing the application function at the application server as specified by the first text message, whereby the first application function is ascertained based at least on the text message destination address.

These and other features of the present invention will be described in more detail below in the detailed description of the invention and in conjunction with the following figures.

BRIEF DESCRIPTION OF THE DRAWING

The present invention is illustrated by way of example, and not by way of limitation, in the figures of the accompanying drawings and in which like reference numerals refer to similar elements and in which:

FIG. 1 illustrates a simplified diagram of the ClairMail architecture, according to one embodiment of the invention;

FIG. 2 illustrates a simplified diagram of the ClairMail authentication request mechanism, according to one embodiment of the invention;

FIG. 3 illustrates a simplified diagram of the authentication mechanism of FIG. 2 in which a rogue request is made, according to one embodiment of the invention;

FIG. 4 illustrates a simplified diagram showing SRA scalability, according to one embodiment of the invention;

FIG. 5 illustrates a simplified diagram showing the ClairMail message protection mechanism, according to one embodiment of the invention;

FIG. 6 illustrates a simplified diagram of a request server, according to one embodiment of the current invention;

FIG. 7 illustrates a simplified diagram of a physical ClairMail server configuration, according to one embodiment of the invention;

FIG. 8 illustrates a simplified diagram showing administration of the ClairMail architecture, according to one embodiment of the invention;

FIG. 9 illustrates a simplified diagram showing the use of web services with the ClairMail architecture, according to one embodiment of the invention;

FIG. 10 illustrates a simplified diagram showing set of steps for effecting the execution of an application function on an application server from a client device, according to an embodiment of the invention; and

FIG. 11 illustrates a simplified ClairMail server, according to an embodiment of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The present invention will now be described in detail with reference to a few preferred embodiments thereof as illustrated in the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. It will be apparent, however, to one skilled in the art, that the present invention may be practiced without some or all of these specific details. In other instances, well known process steps and/or structures have not been described in detail in order to not unnecessarily obscure the present invention. The features and advantages of the present invention may be better understood with reference to the drawings and discussions that follow.

In accordance with one embodiment of the present invention, a ClairMail architecture is advantageously employed to facilitate enhanced information access and retrieval. In a non-obvious fashion, text-based messaging (e.g., email, SMS, etc.) may be extended beyond the person to person communication form, providing both a platform and service directed access to “things” such as transactions, application data or resources on the web. Information access and retrieval can generally be either trusted or non-trusted. Trust generally refers to the degree of confidence that a first party has as to a second party's intent to abide by stated system of rules (e.g., privileges, restrictions, rights, etc.).

In general, the ClairMail architecture generally distinguishes between three types of requests: non trusted, trusted origin, and highly trusted. If the information being transferred between two parties is not particularly valuable in comparison to its general disclosure, or is generally non sensitive in nature, a non-trusted relationship is generally established. Non trusted request may be accepted from anyone/anywhere and results are returned to the sender. This is the simple open or public type of transaction. In one embodiment, the ClairMail architecture may be employed to create non-trusted services in which a text-based messaging address returns non-sensitive information (e.g., news, weather, traffic, etc.). For example, by sending an email to “cmNews@ClairMail.com” with a news topic as the subject of the email, a response may be received containing news on that topic.

Trusted origin requests may be accepted only from a provisioned user (including a set of trusted user addresses) maintained on a registered user list, or derived from an external source (e.g., LDAP, MS Active Directory, etc.). Any request not properly authenticated is subsequently rejected (e.g., spam, etc.), and any reply may only be returned to the appropriate trusted address (and not necessarily to the sender). An SMS address is particularly useful as a reply address since it is unique to the device.

In that way, an unregistered intruder attempting to spoof the ClairMail architecture as a registered user will be detected, and hence not be able to receive confidential information in a reply. In addition, a trusted user address scheme is also resistant to a man-in-the-middle attack. That is, a situation in which a third party, unknown to the other parties, intercepts a message from one party and forwards the message to a second party.

Highly trusted requests are trusted origin requests that require further sender authentication of transaction confirmation. For example, a highly trusted request may be used to transfer funds between bank accounts. A confirmation message may initially be sent to the pre-arranged ‘authentication address.’ As in a trusted request, a registered user defines an address where these confirmation messages are sent, which is not necessarily the same device or protocol from which the request originated.

A confirmation message or authentication token (including a timestamp) that is valid for a short period of time may then be encrypted. Generally, a duration is chosen such that the time required to break the encryption is substantially larger than the time window in which the message is valid. The user may then reply to the confirmation message, perhaps adding some additional information, a personal identification number (PIN) for example, again making the system more secure. That is, if the encrypted message were intercepted and returned without the PIN, the transaction would not be authorized. Once the reply is received by the ClairMail architecture (and the PIN checked appropriately) the transaction is authenticated and executed and ‘marked complete’. As described before, this final step is used to secure against a man-in-the-middle attacks, since a transaction may only be executed once. For example, by typing “cmTransfer@ClairMail.com” with a transfer amount as the subject of the email, and replying to a confirmation, a user can initiate a transfer of funds between two pre-specified accounts.

In addition, a robust authentication mechanism also helps to substantially reduce spam (e.g., unsolicited bulk messages, etc.). Spam has unfortunately encouraged fraudulent advertising and solicitation using electronic messages, since virtually anyone can transmit a substantial number of emails at virtually no cost. Rising to a significant level of concern, most businesses must now protect their messaging systems from floods of spam, as well as avoiding becoming a source of spam themselves, by bouncing bad messages to wrong places.

For example, in an attempt to find a way to connect to the network from which a spammer is blocked, the spammer may send a message with a forged but valid sender address to an invalid destination address at a third site. Consequently, the third site's email server, unable to deliver the message, may in turn send a copy of the undelivered (spam) message back to who it believes is the sender, which in this case is to the forged sender address.

In addition, an invalid destination address may be used in order to execute a denial of service attack. For example, a message from an attacker may be sent to an email server with both an invalid destination address and an invalid return address. As before, since the message cannot be delivered, the email server replies to the non-existent sender, which in turn causes the message to bounce back to the original email server. Consequently, a message transmission loop may be created, eventually consuming sufficient network resources such that legitimate traffic can not be transmitted.

The ClairMail architecture also uses authentication techniques to ensure that information is accessed and transactions executed on behalf of genuine users only. In particular, ClairMail may use an encrypted token which is sent to the client device. The user must reply or submit the token quickly and correctly. The token expires within a few minutes, so an eavesdropper does not have time to decrypt. Once the user replies (optionally with additional password or PIN) the token is canceled, so an eavesdropper cannot use a replicated message to affect a transaction. This technique assures authentic operations using only a simple device, without the need for encryption/decryption in the mobile device. In general, relatively low performance processors are often used in mobile devices in order to increase battery life. Consequently, mobile devices tend not to be optimized for computationally intensive encryption/decryption tasks.

In addition, the ClairMail architecture may allow hosted access infrastructure for managed enterprise access to both internal and external sources. It further may provide a manageable infrastructure for directed transactional access to applications and web services allowing enhanced productivity and owner (total cost of ownership) TCO. In one embodiment, the ClairMail simple request access protocol gives secure directed text-based messaging access to applications and information, enhancing user productivity and reducing support and training costs. That is, no additional software need be installed on the user's desktop computer, laptop computer, mobile device, PDA, smart-phone, wireless-email-device, etc.

Typically, text-based messaging addresses can be created for “actions” or “transactions” within a platform that enables complex actions to be performed from a simple directed request. A single request or message may span multiple applications and provide a consolidated or coordinated result In addition, the results of multiple applicaton queries, each using the same or disparate access credentials, may be consolidated into a unified result.

Text-based messaging addresses stored in the users address book can now define request types. In addition, the requester associated information may come from the profile database at the ClairMail server, and history of requests can be logged.

In general, there are two methods of logging. In a first type, a client log may be maintained at a client device inbox, where a copy of all the sent and received messages are stored, to be accessed and searched later. In a second type, a server log may be maintained at the ClairMail server. It general, the server log records transaction information such as the user name, the task, the time, etc. Consequently the ClairMail server may provide a substantially high level of auditability that is often required by corporate governance guidelines and regulations, such as the Sarbanes-Oxley Act

The ClairMail architecture optimizes traditional text-based messaging applications (e.g., email, SMS, etc.) with SRA (simple request access) addresses, avoiding the limitations of many other approaches such as synchronization, mini-browsers and expensive specialized client applications. Access functions traditionally missing in text-based messaging may be provided as simple alphanumeric text messages (or other sets of indicia) sent to ClairMail enabled server which, in turn, acts upon the messages and returns the required results using a simple electronic message. That is, a ClairMail server may act as the user's personal assistant, by acting as a proxy on the user's behalf.

In a non-obvious way, each ClairMail SRA message has its own unique address. Commonly used SRAs can be kept with the other traditional text-based messaging addresses in an address book for quick access with minimum key strokes. For example, a request might be: “What is the credit limit for customer XYZ?” or “Get a quote for stock symbol XXX?” or “Place order for 100 units of YYY for customer XYZ? or “Sell 100 shares of stock XXX?”

In one embodiment, each of these requests could be sent to the appropriate address@server.com along with additional appropriate parameters (e.g., customer number/name XYZ, Stock Symbol XXX, number of units or shares to buy/sell, item number/name YYY, etc.). The structure of email, in particular, generally offers a large set of addresses which, in turn, provides a large namespace for transaction names.

In addition, although this approach may be optimized for a mobile device, it may be also used from any email-enabled or other messaging capable device. In an embodiment, the request can be sent as a SMS message. In an embodiment, the request can be sent as a web service message. In an embodiment, the request can be sent as IM (instant message). In an embodiment, a web interface may be used to send a detailed request. In an embodiment, multiple protocols may be combined for a given request. In an embodiment, the request may utilize a given protocol for a request, and a different protocol to return the results of the request. A URL of the address may then be bookmarked as a URL for easy retrieval.

In addition, SRA provides a relatively powerful yet simple secure user interface. In general, enterprise applications demand security and authenticity. Security requires that confidential information be kept private and away from eavesdroppers. Whereas authenticity requires that the message is from who it purports to be from. The ClairMail architecture enables substantially robust message authentication by generally accepting messages that contain trusted addresses. That is, unwanted messages or rogue senders can be detected and avoided.

Common message protocols (SMS, SMTP) are generally not secure, and thus can be easily intercepted and falsely replied to. One solution has been the use of public key infrastructure (PKI) techniques, wherein messages are encrypted at the source using a private key then decrypted at the destination using the sender's public key. Although today's mobile devices may have sufficient memory and compute power to use PKI, they generally do not provide mechanism for the secure keeping of private keys.

For example, since a private key (which may be very hard to guess) also tends to be relatively long and hard to remember, it is often secured on a mobile device with a relatively short and memorable PIN or personal identification number (which may be relatively easy to guess). Thus, the local storage of a relatively strong private key with a relatively weak PIN may inadvertently expose the rights and privileges of the device owner to anyone using the device who correctly guesses the PIN.

The ClairMail architecture may avoid the problems of key management in the mobile devices, avoids the differences between devices, avoids the fact that some have a lot of memory and some only little, some are programmed with C/C++ and some with Java, some have SIM cards and some do not, etc.etc. Instead, ClairMail builds upon a simple message protocol (such as SMTP) with a message exchange that passes an encrypted token with the option of using a PIN as well to secure requests. Consequently, computationally intensive encryption may be done at the server (which may have powerful sets of processors) instead of at the client device (which may have a relatively weak processor).

The ClairMail architecture also comprises a hardware/software combination that may be delivered either as a managed service or as an enterprise appliance installed within a firewall. The “front-end” of the ClairMail architecture may be a message server that receives and responds to requests from clients. The “back-end” of the ClairMail architecture comprises a request server, which processes the requests, and accesses the appropriate applications on behalf of the requester. The combination of the message server and the response server in general may function as a proxy server for each client. That is, the application may not necessarily be aware that it is interacting with the ClairMail architecture, as opposed to directly interacting with the client itself

In one embodiment, the message server is the gateway between the external and internal system components, in addition to running the message services (SMTP, SMS, MMS, IM, XMPP, web service, SOAP, XML, WAP, WML, HTTPS, HTTP, etc.) In another embodiment it also runs the secure-web servers for remote-administration and a firewall. For maximum security, no other ports or network connections may be generally made available to the outside world. Message servers can be replicated for scalability and availability. The message server may run the authentication system using data stored in the profile database. Invalid messages are discarded or rejected. Valid messages may be acted upon immediately however, most messages are added to one of the persistent message queues, also stored in the database or on the file system.

In general, within the ClairMail architecture, message queues may be spread across different nodes of a computer cluster in a manner that is optimized for both data consistency and performance. That is, a particular message queue may be simultaneously modified from more than one source (e.g., add, delete, etc.), and yet still maintain a consistent state within the ClairMail architecture.

The request server takes messages from the persistent queues, extracts the input data/parameters from the message, adds profile information such as user credentials, and passes them to the client application. That is, the request server makes the desired information-access or executes the transaction specified by the request and returns results. The request server formats the results into a simple message and returns them to the user. Request servers can be replicated for scalability and availability. Each server takes the next message from the queue, and does not interfere with others.

Request servers can often use one or more client application machines to run the applications. Client machines can also specialized to run only one or a few applications. This is useful when the client applications need a lot of computing resources, or perhaps need dedicated access to external network connections or databases. In these cases, different queue are used. The message servers direct messages to the appropriate queue and only that set of request servers take messages from that queue.

The resulting system is substantially scalable in all aspects (e.g., message servers, request server and client application machines can all be replicated) ensuring substantially high availability, substantial scalability (from low-cost to high-capacity at the right price) with substantially easy maintenance and upgrade paths. In general, small, low-cost systems are needed for organizations with a small mobile workforce, yet large enterprises will exceed the capacity of a single computer.

The ClairMail architecture also enables substantially parallel operations. For example, the message server can be run on a single computer or a set of parallel computers. Additional computers can be added simply, at any time. A single logical database is used to hold the user-profile data and conventional database replication is employed to scale the capacity and performance as required. The request servers can run alongside the database in small installations or can be distributed across a set of servers to meet the needs of the largest. Client applications may be added to meet the workload and response times required.

The ClairMail architecture also enables 24×7 availability. By enabling inherent redundancy, ClairMail architecture allows both scalability and system availability in the event of failure of any one component. Messages can be processed by any of the message servers. For example, should any request server or client application machine fail, others will be available to continue the service. If one fails while processing a request, a timeout will occur and the next request server will take over automatically.

The ClairMail architecture may also be reliable. Reliability is a measure of the difference between expected system behavior and actual system behavior, including un-expected system input. The ClairMail architecture enables false messages to be rejected by for example, forward and reverse DNS lookup checking to ascertain whether the sender's IP address and domain match. Also, false message detection may be accomplished using modern techniques such as Sender Policy Framework (SPF) where valid sending IP addresses are listed in the domain DNS. In addition, since open systems are susceptible to denial-of-service attacks (DoS), the ClairMail architecture has special techniques to detect and respond to such attacks. Early identification of bad senders ensures that little computer resources (CPU time, memory, log files) are wasted and “tarpit” techniques are used to slow down multiple inputs from one place. Although genuine users are generally unaffected, rogue users are slowed down to a rate that cannot cause loss of service.

System monitoring and administration is also automated in order to keep costs low. When required, these monitoring and administration functions are available remotely using secure-web access. Suitably authorized users can manage ClairMail system from any web browser.

Referring now to FIG. 1, a simplified diagram of the ClairMail architecture is shown, according to one embodiment of the invention. The user operates the client device 102, commonly a mobile device such as a Blackberry or PDA or a laptop or even a non-mobile computer. A mobile phone, especially one of today's smart-phones, is fast becoming the mobile device of choice.

Client device 102 connects to the ClairMail SRA (simple request access) server 106 (proxy server) over some kind of wide area network 104, probably a combination of a wireless network and the Internet. SRA server 106 commonly comprises a message server [described below] and a request server [described below]. SRA messages are used to communicate the request much like a remote procedure call (RPC) mechanism is used with client APIs.

In order to take maximum advantage of the wide variety of devices and networks and to avoid the complexity of RPC protocols like CORBA, the ClairMail architecture may use human readable addresses and text for these messages. This substantially ensures access from all devices, since a simple messaging capability is all that may be required for security and authenticity.

SRA server 106 may maintain a user profile database 108 which is used for user authentication, request augmentation, and personalization, wherein information such as user preferences, default values, and credentials may be stored and encrypted. For example, non-trusted requests, like “Get a quote for Stock with Ticker Symbol XXX” or “Look up a phone number” do not require authentication. Trusted request are verified against registered user list. Highly trusted requests, as previously described, usually require both verification against a registered user list, as well as a confirmation message or authentication token may initially be sent to the pre-arranged ‘authentication address,’ optionally with an additional PIN. Once SRA server 106 receives a request message (authenticated if required), it may act upon it directly, it may connect over a WAN (wide area network) 111 (e.g., Internet, etc.) to publicly available internet servers 116 a-b or it may pass the request on via LAN (local area network) 114 or a wireless network (not shown) to application servers 120, which may in turn be coupled to a persistent data store, such as database 112. For many requests, the SRA server will act upon behalf of the requester and uses data from the user profile database to access private information over the Internet or login to a client application 110 on behalf of the user. In an embodiment, access to client application 110 is done through the user interface, as the user themselves would do. For example, SRA server 106 may intercept GUI (graphical user interface) based transactions (e.g., text, mouse movement and clicks, etc.) that would normally be used by client application 110 to interact with a human user.

The requesters profile contains user names and optionally, passwords for each request, ensuring that private information (e.g., user names, passwords, etc.) may not be sent over the public WAN 111. In addition, the user profile database may be secured behind appropriate firewalls. In one embodiment, SRA server 106 may only have three or four ports open to the WAN (e.g. SMTP SMTP, SMS, MMS, IM, XMPP, web service, SOAP, XML, WAP, WML, HTTPS, HTTP, etc.) in order to maintain security. In another embodiment, the client application is part of a typical client/server enterprise application; the client connects over a local area network, probably inside the enterprise firewall, to the application servers and databases.

Referring now to FIG. 2, a simplified diagram of the ClairMail authentication request mechanism is shown, according to one embodiment of the invention. Initially, client device 102 may send a SRA message to get permission for the access or transaction at 1. SRA server 106 may use the name of the message sender to look up the user's profile 108 at 2. Part of the profile is the address used to get permission. Typically, this may be the same device, although it need not be, and may utilize a different messaging protocol.

SRA server 106 may then create an encrypted token and an associated mailbox using that token. The system may then send the authentication request back to the user at 3. Note, this mailbox address generally never existed before and will expire in a few minutes, so an eavesdropper may not be able to learn about this beforehand and may have only a few minutes to try to crack the encrypted token. The choice of token key length and short time-to-expire substantially ensures security. Client device 102 (the user) replies to the authentication request, adding an additional PIN for the more secure requests. Once SRA server 106 receives the authentication reply at 4, the temporary mailbox may be destroyed and the original request is generally marked as authentic. SRA server 106 may then pass the request on to the appropriate client application 110 at 5, and returns the results to the SRA server 106 at 6, and then finally to client device (and the user) at 7.

Referring now to FIG. 3, a simplified diagram of the authentication mechanism of FIG. 2 in which a rogue request is made, according to one embodiment of the invention. Rogue client 302 attempts to penetrate the ClairMail architecture by sending a request to SRA server 106 with a forged the “From:” address at 1. SRA server 106 may then look up the user in the profile for authentication. An encrypted token and a temporary mailbox may then be created.

Subsequently, the authentication request is forwarded to one of the trusted addresses of genuine user 304 at 3. That is, the genuine user may receive a spurious authentication request and sending address. Genuine user 304 may simply ignore it. However, genuine user 304 may reply negatively at 4, and subsequently receive a confirmation message from SRA server 106 indicating that client application 110 is protected at 5. This negative reply may be used to identify and block rogue 302 from further access. As previously described, the use of a set of trusted address allows SRA server 106 to operate as a spam-free message server, particularly when used with common internet protocols, such as SMTP, that can easily be forged.

Referring now to FIG. 4, a simplified diagram showing SRA scalability is shown, according to one embodiment of the invention. In general, all components of SRA server 106, as shown in FIG. 1, can be scaled up to meet arbitrary demands for performance and availability, which is important not only to meet the needs of a large enterprise but also to deploy the right-sized system at the lowest cost with simple growth paths.

The message servers 402 a-c (e.g., SMTP, etc.) may distribute load with conventional IP-spraying techniques such as round-robin DNS or Cisco's Local Director. The message queues, that may be stored on database 108, may be designed for multiple-readers and writers accessing over a network at the same time, with the minimum of necessary locking. This ensures high performance with high reliability. Capacity can be expanded by storing different queues on different systems.

Request servers 404 a-c may take messages from their designated queues process them in turn, and subsequently forward the messages to the appropriate client applications 406 a-b. Since as soon as one request is finished, the next is processed, the load may be naturally distributed. Fewer request servers may offer a lower-cost system that would have higher latency in response times when the system is busy. Generally more request servers 404 a-c would keep latency to the minimum even when systems are busy, at additional cost. In addition, it may be easy to add request servers 404 a on-the-fly, so systems can be scaled to meet the processing and performance needs.

Referring now to FIG. 5, a simplified diagram showing the ClairMail message protection mechanism, according to one embodiment of the invention. Incoming messages are screened so that minimal computing resources are wasted on rogue or error messages. This may help to prevent Denial of Service attacks as well.

Initially, the source IP address may be compared against blacklists 408 of known spam sources, and those messages are dropped immediately without even accepting the message into the system at 1. Several additional checks are made on the message protocol and header information—items that are often wrong on forged messages, such as no DNS MX record for the source IP address, no DNS entry for the source—and these too are immediately rejected at step 2.

A common function of the ClairMail authentication system may be to send ‘bounce’ messages back to the source—yet when the source is forged, the bounce message ‘bounces’ again. These double-bounce messages are generally errors (sometimes transient errors) so they are logged but processed no further. These early checks may reduce the load on the server and help protect it from DoS attacks. Each check can be enabled or disabled for everyone or for specific IP addresses or ranges of IP address. This is important, since we are in the unfortunate state today, where many large organizations fail to set up their message sending servers correctly (e.g. missing DNS entries, no reverse DNS, missing MX entries) and yet they are genuine message sources and need to be accepted. The ClairMail administrator may make these changed dynamically. Additional spam filtering may be available as well, however as the ClairMail authentication may work better, some of these checks are commonly disabled.

Next, authentication messages from previously unknown users are checked at 3. If a message is addressed to one of the special mailboxes with an encrypted name, and if it is a valid response (within timeout, with PIN if required, etc.), that user is ‘authenticated’ and their profile is added/updated in user profile 108.

An “authenticated” confirmation message is then returned to client device [not shown] at 4. The particular details of who may be authenticated can vary from system to system. A system open to the public, could authenticate all users (unless blacklisted). A private system might only allow users known in some other database/directory (e.g., LDAP, MS Active Directory, etc.) and may not need to utilize “authenticated” confirmation messages.

If the message is not an “authenticated” message, the message is checked to see if the user is known at 5 (i.e., the source address of the message matches one in the user profile database) or if non trusted access to this request is allowed. If not, the user is unknown and an authentication message may be generated (with an encrypted key) and returned to the user at 6. If the source address is forged or and invalid, this reply might be queued, lost or will bounce, so the source address remains unknown.

The request is then parsed and dispatched for appropriate processing at 7. Some requests may cause an immediate reply 406 at 8, while others may be placed on a persistent queue 510, where they are deferred 504 for further action.

Referring now to FIG. 6, a simplified diagram of a request server is shown, according to one embodiment of the current invention. Request server 404 generally takes the next request from a request queue 602 and depending upon the type of request, processes it as shown.

The ClairMail architecture uses rapid development techniques, usually in the form of simple scripts that match input and output parameters from the request message with the application interface. Complex requests may be built up from combinations of simple scripts, for instance “lookup product from UPC” and “get price quote for product” are combined to create a new request “get price quote from UPC”. Note that the ClairMail architecture is designed to allow multiple request servers running in parallel. This is important for scaling systems to meet capacity requirements.

In addition, individual request servers can be specialized to handle specific requests which are important when special software or hardware installations are required. Type 1 requests generally represent the use of modern web services, structured requests made of HTTP guided by the Web Service Definition Language WSDL documents for each service. The ClairMail request server matches the unstructured input parameters from the message and copies them into the structured XML document as defined by the WSDL parameters. Results from the XML document returned from the Web Service request are extracted using the WSDL output parameters, formatted into text appropriately using XSLT and put into the reply message for the user. A ClairMail script is used for this parameter matching and formatting permitting rapid script development and simple maintenance.

Type 2 requests generally represent the use of less structured internet requests, such as fetching a web page. In this case, the ClairMail script copies the input parameters into the appropriate request (an HTTP GET or POST, for instance) and also directs the extractions of returned results. Wherever possible, the HTML results are converted into XML, and the same structured extraction and formatting techniques of Type 1 are used. Type 2 scripts may be a little more complex than Type 1 scripts in order to deal with variations inherent in using less structured requests and replies. Nevertheless, they tend to be much simpler than Type 3 requests (see next section) and still offer the benefits of the Rapid Development techniques.

Type 3 requests generally represent the conventional way to access application data from a new application—write a new client program. A program is written to take the input parameters from the request and pass them to the application using the API provided by vendor and then return the results. It is generally known that development and maintenance of new client programs may be substantially expensive, and so Type 3 requests are usually avoided in ClairMail Systems. Nevertheless, they are available as and when required, for example, if Type 1 and Type 2 are not available.

Type 4 requests generally represent a new, rapid-development approach to solve the problem of application access. It uses a novel “Visual API” using screen-scraping, cut and paste, and OCR techniques. A script directs the matching of input and output parameters to the input and output fields on the screens of an existing application. This component of the ClairMail server pastes the input parameters into the input fields and extracts output parameters as directed by the script. Type 4 requests are used to access existing and legacy applications without the need for expensive programming. This method may leverage browser based or terminal session applications including Citrix, VNC, MS Terminal Server, VT100, etc. Scripts are generally simple, quick to write, and easy to maintain.

Referring now to FIG. 7, a simplified diagram of a physical ClairMail server configuration is shown, according to one embodiment of the invention. The front end (facing Internet 112) may comprise two or more computers running the message software (e.g., SMTP, etc.) as well as the firewall and web servers for administration 702 a-b. A minimum of two servers is suggested for continuous availability in the event of failure or during maintenance.

Whereas the back end (facing the internal network) may run database server or RAIDb (redundant array of independent databases) 108 which may be stored on a reliable file system. Larger systems duplicate the database server and replicate the database using conventional database techniques for high availability, such as RAID file system 704 (redundant array of independent disk). Additional machines are included as required to run the client applications. Some of these may require access to the enterprise servers. This is usually done using a private network connection, or perhaps via a virtual private network (VPN), over the public internet. Although the front end and back end ClairMail servers may run the Linux operating system, client application 110 may run on different operating systems, such as Microsoft Windows, since it is the only host for many applications.

For example, ClairMail Inc. runs the public ClairMail service @ClairMail.com which is open to the public and registered users. Enterprise customers run a complete ClairMail system for their own users which may be run by ClairMail Inc. on behalf of a customer as a managed service, or installed at the customer's site.

Referring now to FIG. 8, a simplified diagram showing administration of the ClairMail architecture, according to one embodiment of the invention. In general, all of the server functions of a ClairMail system may have remote administration built-in. A secure network interface (e.g., HTTPS, SSH, etc.) may be hosted on the message servers and used to access the web server administration applications 802 a-b which include the ClairMail simple request access database, the message queues, system logs, blacklists etc. In addition, client application 804 may also have integrated remote control functionality. Remote administration of these machines is possible using either a remote control client application or via the web using a remote control applet. In general, ClairMail servers run un-attended. For example, log file rollover is automatic, message queues grow and shrink as required. When it is required, system monitoring and administration functions may be easily performed by any suitable authorized user from a web browser or management console.

Referring now to FIG. 9, a simplified diagram showing the use of web services with the ClairMail architecture, according to one embodiment of the invention. A web service is generally a standardized way of integrating applications into a SOA (services oriented architecture) using the XML, SOAP, WSDL and UDDI open standards over an Internet protocol backbone. XML is used to tag the data, SOAP is used to transfer the data, WSDL is used for describing the services available and UDDI is used for listing what services are available.

Web services allow different applications from different sources to communicate with each other without time-consuming custom coding, and because all communication is in XML, Web services are not tied to any one operating system or programming language. For example, Java can talk with Perl, Windows applications can talk with UNIX applications, without special programming.

In this example, ClairMail services 906 a-b are SRA servers 106 as shown in FIG. 1, that allow users 902 a-c to access web services from web service providers 908 a-c. That is, ClairMail services 906 a-b are generally able to translate incoming text messages from users 902 a-c into the appropriate web service protocol. [00086a] Note that one request can access multiple web services (906 b accessing 908 a and 908 c) to answer one request.

ClairMail services 906 a-b may accept a variety of input message types and protocols (SMTP, SMS, etc) from users 902 a-c, and in addition XML messages in the form of Web Service calls from service providers 908 a-c. ClairMail services 906 a-b can also publish the availability of their particular web services in the standard way using UDDI.

FIG. 9 shows multi-tier service where 908 a-c are also ClairMail servers. Users 902 a-c access ClairMail server 906 a-b which in turn access one or more ClairMail servers 908 a-c using web services.

The ClairMail architecture may provide significant advantages for the both users 902 a-c and service providers 908 a-c, such as user profile caching. For example, user 1 902 a has registered with ClairMail service 1 906 a and given all necessary profile and preference information which is stored in the user profile database 108 a. ClairMail service 1 906 a can in turn access a web service from service provider 2 908 b, and subsequently transfer a copy of the user 1 profile from user profile database 108 a to service provider 2 908 b user profile database 910 b. Generally, the protocol between the ClairMail servers is secure and trusted. Once authenticated, the message may be passed securely (e.g. encrypted using SSL connections) to another server which can trust the user's authenticity.

Should user 1 902 a want to add access to a new service provider, user 1 902 a can direct ClairMail service 1 906 a to connect to a new service provider using a web service protocol, and again transfer user 1 profile from user profile database 108 a to the new service provider. Benefits to the user include avoidance of re-entering the same registration information, as well as maintaining a single copy of a user's profile (i.e., names, preferences, passwords, etc.). Benefits to the web service provider include a simplified security interface in which to interact with users.

Another advantage that this architecture provides is the creation of a “control point”, a single place where user's access can be monitored, managed and logges. This might used for billing or reporting or auditing, for example.

Referring now to FIG. 10, a simplified method for effecting the execution of an application function on an application server from a client device, the client device being coupled to a proxy server, the proxy server being further coupled to the application server that executes an application implementing the application function, is disclosed, according to an embodiment of the invention. Initially, at 1002, a text message is received at an text message destination address at the proxy server from the client device. In an embodiment, the client device is coupled to the proxy server via a first network, and proxy server is coupled to the application server via a second network. In an embodiment, the first network is one of a wide area network, and a wireless network. In an embodiment, the second network is one of a wide area network, a wireless network, and a local area network. Next, at 1004, an authentication message is sent to a user at an text message confirmation address that is different from the text message origination address. In an embodiment, the authentication message is transmitted to the user using a first protocol that is different from a second protocol employed to transmit the text message from the user.

In an embodiment, the first protocol and the second protocol includes at least one of SMTP, SMS, MMS, IM, web service, SOAP, XML, HTTPS, and HTTP. In an embodiment, the text message confirmation address represents a non-persistent text message address that is configured to be inactivated after said authenticating. In an embodiment, the text message destination address is stored in a messaging address book on the client device. Finally, at 1006, if the user is authenticated, executing the application function at the application server. For example, the application function may include checking a credit limit, getting a stock quote, placing an order, selling shares of a stock, looking up a product from a UPC code, and getting a price quote for a product.

Referring now to FIG. 11, a simplified ClairMail server is shown, according to an embodiment of the invention. As previously described, a user commonly operates client device 102, such as mobile device (i.e., Blackberry, PDA), laptop or non-mobile computer.

In a common configuration, ClairMail server 106, as shown in FIG. 1, connects client devices 102, over a wide area network 104 (i.e., wireless network, Internet, etc.) to a set of applications and services 1124, and is further comprised of a set of logical modules. Service guard module 1104 substantially protects ClairMail server 106 from intrusion and denial-of-service attack from hostile devices on wide area network 104. In general, an intrusion is any set of actions that attempt to compromise the integrity, confidentiality or availability of a residing resource on or coupled to ClairMail server 106. A denial-of-service attack is generally a type of attack designed to substantially incapacitate ClairMail server 106 by flooding it with useless traffic.

In an embodiment, service guard module 1104 functions as a firewall, substantially preventing unauthorized access to or from wide area network 104, to ClairMail server 106. All messages to or from client devices 102 are generally filtered by service guard module 1104. For example, service guard module 1104 may use a packet filtering technique, in which each packet entering or leaving the wide area network 104 is accepted or rejected based on a set of defined rules. In addition, service guard module 1104 may further include sub-modules, such as email guard 1104 a, SMS guard 1104 b, IM guard 1104 c, HTML guard 1104 d. Email guard 1104 a protects ClairMail server 106 from electronic mail. In general, because email allows a message to be broadcast to a large group or recipients at once, email messages are often used to transport viruses between computers, commonly as “attachment” to the message that contains a malicious program which executes when opened.

SMS guard 1104 b generally protects service guard module 1104 from potentially hostile SMS messages. SMS, or short message service, allows short text messages to be sent to mobile phones, fax machines, and/or IP addresses. In general, messages must be no longer than 160 alpha-numeric characters and contain no images or graphics. IM guard 1104 c generally protects against IM messages. IM, or instant message, is a type of communications service that enables substantially real time communication over the Internet. HTML guard 1104 generally protects against message containing HTML code. HTML, or HyperText Markup Language, is commonly an authoring language used to create documents on the World Wide Web. HTML generally defines the structure and layout of a Web document by using a variety of tags and attributes.

Service guard module 1104 is further coupled to request parser module 1106. In general, depending on the message type (e.g., email 1106 a, SMS 1106 b, IM 1106 c, HTML 1106 d), request parser module 1106 divides the text of any request from client devices 102 into small components that can be analyzed. For example, a ClairMail request may be structured in the format instruction—variable@server.com, where instruction is the request to be executed by ClairMail server 106, such as the location of nearest restaurant, the current weather, or the transfer of funds, variable is additional information, such as a location, name, account number, encrypted tokens as previously described, etc., and server.com is the name of the particular ClairMail server upon which the user wishes to execute the instruction. Parsing is often divided into lexical analysis and semantic parsing. Lexical analysis concentrates on dividing strings into components, called tokens, based on punctuation and other keys. Semantic parsing then attempts to determine the meaning of the string or instruction.[00097] Access control manager module 1108 is coupled to request parser module 1106, and further controls the mechanisms and policies that restrict access to computer resources on ClairMail server 106. In an embodiment, an ACL, or access control list is used. An ACL is a set of data that informs the ClairMail server 106 which permissions, or access rights, that each user or group has to a specific system object, such as a service or application 1124. In general, each object has a unique security attribute that identifies which users have access to it, and the ACL is a list of each object and user access privileges such as read, write or execute.

Request action bus module 1110, couples access control manager module 1108 to service connector module 1112. In a common implementation, once users are authenticated by access control manager module 1108, user requests are queued in request action bus module 1110, where they are pulled off by service connector module 1112, based on scripts in service scripts module 1132, when the appropriate application or service 1124 becomes available. A script is a macro or batch file with a list of ClairMail server 106 commands that can be executed without user interaction. In an embodiment, a ClairMail script language may be used to write scripts for service scripts 1132. In an embodiment, the order in which ClairMail server 106 executes user requests on request action bus module 1110 the same order that they were placed on the queue. In an embodiment, some user requests are given higher priority than others.

Inbound messages from a user may be augmented with user profile information, such as credentials, preferences, default values, trusted reply path, reply protocol, response formatting, authentication method required, etc. This generally allows for concise requests to minimize user typing yet provides rich data for the processing which may perform complex operations. This method avoids the need to send credentials over the network or even to put the credentials at risk to malicious software or the sending device.

Service connector module 1112 includes the set of connectors and adapters for connecting to appropriate applications or services 1124. WSDL connector 1112 a allows ClairMail server 106 to connect to web services 1124 a. WSDL is generally an XML-formatted language used to describe a Web service's capabilities as collections of communication endpoints capable of exchanging messages. In an embodiment, WSDL connector 1112 a may connect to a UDDI directory. UDDI, or universal description, discovery and integration, is generally a web-based distributed directory that enables businesses to list themselves on the Internet and discover each other, similar to a traditional phone book's yellow and white pages.

HTML connector 1112 b allows ClairMail server 106 to connect to web apps 1124 b. As previously described, HTML is commonly an authoring language used to create documents on the World Wide Web. HTML connector 1112 b allows portions of previously created web pages to be extracted and delivered to client devices 102.

UI connector 1112 c allows ClairMail server 106 to connect to client apps 1124 c through the UI, or user interface. A UI is commonly an interface with a set of commands or menus through which a human user communicates with a program. In order to substantially reduce the need for additional programming, UI connector 1112 c can mimic a human user, automatically querying and extracting relevant information from remote user applications, such as a CDROM encyclopedia or map program.

API connector 1112 d allows ClairMail server 106 to connect to app servers 1124 d. API, or application program interface, is generally a set of routines, protocols, and tools for building software applications. An app server, or application server, is generally a program that handles application operations between users and backend applications or databases. App servers are typically used for complex transaction-based applications. For example, API connector 1112 d may connect ClairMail server 106 to a SAP application server, allowing a user to query customer order status from client device 102.

Service admin module 1114 allows a ClairMail administrator to securely manage a collection of ClairMail networks, computers, and databases. Profile management module 1116 allows ClairMail Server 106 to maintain a set of service and resource profiles for each user. For example, a user may desire requests to be customized depending on the type client device 102 through which the request is made.

Service provisioning module 1120 allows a ClairMail administrator to provide users with access to services and applications 1124. In general, provisioning comprises allowing a particular user access to a particular service or application 1124, based on user identity and a particular profile stored in profile management module 1116.

Service monitoring module enables a ClairMail administrator to create an inventory of all the hardware and software on the network and to perform diagnostic tests. Usage reporting module 1122 monitors resource utilization within ClairMail server 106, as well as user access to services and applications 1124.

In an embodiment, transaction state is maintained through the use of temporal mailboxes. Commonly on the Internet, transaction state is often maintained through the use of browser cookies. A cookie is typically a small message given to a Web browser by a Web server. The browser stores the message in a text file, and sends the message back to the server each time the browser requests a page from the server. By allowing the Web server to identify a particular browser (or user) between successive Web page requests, cookies provide a rudimentary form of transaction security. That is, the particular browser that begins the transaction (i.e., a user purchasing a book from Amazon.com) is the same browser that completes the transaction.

However, unlike browsers, mobile device applications are generally optimized for communication and not transactions. That is, although mobile devices are fairly good at sending and receiving voice and text messages, such as email and SMS, the physical size and computational capabilities of many mobile devices make them less effective as a user interface to Internet applications, such as Web servers. Subsequently, there is generally no equivalent to a cookie for maintaining transaction state in mobile device messaging applications.

In a non-obvious way, a temporal mailbox may be used as a substitute for a cookie in order to maintain transaction state. That is, instead of locally storing a cookie, the client device is granted a set of unique return address or temporal mailboxes. A response to a specific temporal mailbox signals a particular change in state for a particular client device to the ClairMail server. For example, for a transaction that may involve multiple requests, such as selecting a path through a menu tree, responding to a particular temporal mailbox corresponds to a specific menu choice, which may cause the next level of choices to be transmitted to the client device.

Compare this with web pages and hyperlinks. Navigation is made simple by clicking the links. Temporal mailboxes are used in messages as simple links to click. The state information associated with the particular temporal mailbox conveys all the necessary navigation and transaction information. Using temporal mailboxes in the manner makes the messaging system as easy to use as the web.

For example, a user wishes to access a SAP application through a ClairMail server, in order to view the total amount of the most recent order for a particular customer. Once the user has been authenticated by the access control manager, the user is able to send a first text message to a particular email address at the ClairMail server, which subsequently instructs the ClairMail server to communicate with the SAP application, based on previously defined profile information and scripts. For instance, the server address may be entered as cm-SAP@server.com, with a subject of namecustomername, where customername is the name of the particular customer of interest, and server.com is the name of the particular ClairMail server upon which the user wishes to execute the instruction.

The ClairMail server would then return a text message to the client device with a simplified menu in the body of the message:

Invoices: cm-SAP-10000@server.com

Current Orders: cm-SAP-20000@server.com

Back Orders: cm-SAP-30000@server.com

Other: cm-SAP-40000@server.com

Return: cm-SAP-50000@server.com

By sending a text message to cm-SAP-20000@server.com, a new message will be transmitted with a simplified sub-menu in the body of the message:

total order amount to date: cm-SAP-11000@server.com

quarterly order amount to date: cm-SAP-22000@server.com

monthly order amount to date: cm-SAP-33000@server.com

last order amount: cm-SAP-44000@server.com

Other: cm-SAP-55000@server.com

Return: cm-SAP-66000@server.com

Sending a text message to cm-SAP-44000@server.com, will instruct the ClairMail server to transmit the total amount of the last order for customer customername.

Note that the temporary mailbox name may be encrypted for added security. Since the user can click the link and does not need to type the address, a long encrypted key can be used if such is desired.

In an embodiment, two-factor authentication may be used with the ClairMail architecture. As previously described, highly trusted requests may require the sender to confirm the transaction, such as with a confirmation message or authentication token. However, if the communication channel or path is compromised, an intruder may intercept the confirmation message or authentication token and correctly respond, causing the ClairMail server to believe that the real user has properly confirmed the transaction. In order to increase the level of security, at least two communication channels may be used, a primary transaction channel and a secondary confirmation channel.

For example, a bank may have a ClairMail server coupled to an ATM machine for authentication purposes. A customer wanting to withdraw above a fixed amount from an ATM (i.e., >$300) will receive an SMS message with a particular OTP (one time PIN) on the user's client device (i.e., mobile phone, PDA, etc.) which will need to be entered into the ATM within a short period of time (e.g., three minutes) in order to complete the transaction.

In another example, a customer using a browser and wanting to transfer money from the bank's website to a third-party account would receive the SMS message with an OTP that would need to be entered into the browser window. In another example, the ATM machine or bank website generates the security serial number that must be transmitted from the client device to the ClairMail server via SMS or email, before the transaction is authorized.

In an embodiment, the serial number or token is generated by a smart card, such as a RSA SecurID Authenticator device. A smart card is generally a small electronic device about the size of a credit card that contains electronic memory, and possibly an embedded integrated circuit (IC). Smart cards containing an IC are sometimes called Integrated Circuit Cards (ICCs). When the user wishes to withdraw or transfer funds, a message is received on the client device requesting the then current token. In an embodiment, the confirmation message is sent to a user other than the user who is making the ClairMail server request. For example, before an employee can transfer or withdraw funds, a confirmation message is sent to the employee's supervisor for authorization.

In an embodiment, the ClairMail architecture can use a mobile device SIM for transaction authorization. Short for subscriber identity module, a SIM is generally, a smart card inside of a GSM cellular phone that encrypts voice and data transmissions and stores data about the specific user so that the user can be identified and authenticated to the network supplying the phone service. The SIM also stores data such as personal phone settings specific to the user and phone numbers. A SIM can be moved from one phone to another and/or different SIMs can be inserted into any GSM phone. Since identity information on each SIM is generally unique, a transaction may be securely authorized by first transmitting a confirmation message to the mobile device, encrypting the confirmation message with the SIM card, and returning the confirmation (or a cryptographic hash of the confirmation) to the ClairMail server.

In an embodiment, the ClairMail server provides single signon functionality. An authentication process in a client/server relationship, single signon allows the user, or client, can enter one name and password and have access to more than one application or access to a number of resources within an enterprise. Single signon generally reduces the need for the user to enter further authentications when switching from one application to another.

In an embodiment, the ClairMail server can connect with client devices that are enabled with XForms, a W3C standard. Unlike standard HTML web forms which generally require that each form be transmitted to the web server after data entry, XForms enabled applications generally allow a set of forms to be processed locally and then subsequently transmitted to a web server as an XML document. In addition, by using XML for data definition and HTML or XHTML for data display, XForms enabled applications can generally be customized for different user interfaces, such as mobile phones, handheld devices, and Braille readers for the blind.

In an embodiment, a ClairMail sever may communicate with a RFID-enabled mobile device. Short for radio frequency identification, an RFID system generally consists of an antenna and a transceiver, which radiates the radio frequency and transfer the information to a processing device, and a transponder, or tag, which is an integrated circuit containing the RF circuitry and information to be transmitted. Unlike bar coding technologies, RFID eliminates the need for line-of-sight reading and can be done at greater distances. There is significant advantage for the user who would otherwise have to type the information. There is also significant advantage for the mobile RFID device; it needs to communicate with some server, and the ClairMail Architecture offers a simple, low cost and effective solution to this problem.

For example, if a user wants drug interaction information between two medicines, an RFID-enabled mobile device may first read RFID information on or in each medicine container. This RFID information is then be transmitted to a ClairMail server which, in turn, queries a drug interaction database service. The ClairMail server may then send the specific drug interaction information as a reply to the mobile device as a customized text message.

In an embodiment, a ClairMail sever may communicate with a GPS-enabled mobile device. Short for Global Positioning System, GPS is generally a worldwide satellite navigational system formed by 24 satellites orbiting the earth and their corresponding receivers on the earth. The GPS satellites continuously transmit digital radio signals that contain data on the satellites location and the exact time to the earth-bound receivers. By using three satellites, GPS can calculate the longitude and latitude of the receiver based on where the three spheres intersect. By using four satellites, GPS can also determine altitude. For example, if a user wants location specific information, such as the location of a restaurant, the user's current location may be automatically transmitted to the ClairMail server by the GPS-enabled mobile device, instead of manually entered by the user. The ClairMail server may then respond with a text message including directions to the desired address from the current address. As with the mobile RFID reader, this represents a significant advantage to the user, who does not to enter the location information manually, which tends to be tedious and error prone.

In an embodiment, address book entries in the mobile device may be used for command syntax help and/or hints. For example, a user can query a ClairMail server for a general help menu by sending a message to cmhelp@server.com, where cmhelp is the particular help request, and server.com is the name of the particular ClairMail server at which the user wishes to execute the help instruction. Upon receipt, the following simplified general help menu may be returned as the body of a text message:

-   -   mailto:cmCurrency@server.com     -   Lookup currency at GoCurrency.com     -   mailto: cmDictionary@server.com     -   Lookup words at www.dictionary.com     -   mailto: cmDirections@server.com     -   Driving Directions from www.mapquest.com     -   mailto:cmFroogle@server.com     -   Froogle search for products froogle.google.com     -   mailto:cmGoo@server.com     -   Google search for PDA display google.com/palm         More specific help can be obtained, for example, by sending a         particular request with the word “Help” in the subject.

In an embodiment, a set of abbreviations may be used in order to reduce the amount of user typing. For example, a user can query a ClairMail server for a set of abbreviations by sending a message to cmkeyget@server.com, where cmkeyget is the abbreviation or key request, and server.com is the name of the particular ClairMail server at which the user wishes to execute the help instruction. Upon receipt, the following simplified general help menu may be returned as the body of a text message:

-   -   SFO—address 1     -   LAX—address 2     -   HOME—address 3

A user can then modify existing keys, or add new ones, and then transmit the text to cmkey@server.com. Subsequently, the user can request directions from his home to the San Francisco Airport by sending a text message to cmdirection:HOME:SFO@server.com.

In an embodiment, the key of LOCN is assumed to be the default key for requests that involve location, when a required key is missing. In an embodiment, the user's present location if known (i.e., by a GPS-enabled user device, previously entered by the user, etc.) is assumed to be the current location key for requests that involve location. For example, sending a message to cmstarbucks@server.com, with no subject, will generally cause the ClairMail server to return directions to the nearest Starbucks from what it believes is the user's current location.

While this invention has been described in terms of several preferred embodiments, there are alterations, permutations, and equivalents which fall within the scope of this invention. The titles and abstracts are provided herein for convenience and should not be used to interpret the invention in a manner so as to limit the scope of the claims herein.

Advantages of the invention include architecture for general purpose trusted personal access system and methods therefore. Additional advantages include a hosted access infrastructure for managed enterprise access to both internal and external sources, a manageable infrastructure for directed transactional access to applications and web services, and enhanced productivity and lower total cost of ownership (TCO).

Having disclosed exemplary embodiments and the best mode, modifications and variations may be made to the disclosed embodiments while remaining within the subject and spirit of the invention as defined by the following claims. 

1. A method for effecting the execution of an application function on an application server from a client device, said client device being coupled to a proxy server, said proxy server being further coupled to said application server that executes said application function, said method comprising: receiving at said proxy server from said client device a first message, wherein said first message includes a first message destination address and a first message origination address, and wherein said proxy server is a final destination of said first message, and wherein said first message includes a first human-readable input parameter; and wherein said first message conforms to a first text-based user-to-user messaging protocol; transmitting from said proxy server to said client device a first response, wherein said first response includes a plurality of unique return addresses for signaling respective particular changes in state for said client device, wherein said unique return addresses are unique for said client device; receiving at said proxy server from said client device a second message, wherein said second message is indicative of a user selection of one of said plurality of unique return addresses, and wherein said proxy server is a final destination of said second message, and wherein said second message pertains to a request to execute said application function, and wherein said second message includes a second human-readable input parameter; and wherein said second message conforms to a second text-based user-to-user messaging protocol; selecting in said proxy server said application server based on one or both of said first human-readable input parameter and said second human-readable input parameter; generating in said proxy server a third message utilizing one or both of said first message and said second message, wherein said third message is for use by said application server; and transmitting to said application server from said proxy server said third message, to cause said application server to execute said application function based on said third message.
 2. The method of claim 1 wherein said client device is coupled to said proxy server via a first network, and said proxy server is coupled to said application server via a second network.
 3. The method of claim 2, wherein said first network and said second network are the same.
 4. The method of claim 2, wherein said first network and said second network are not the same.
 5. The method of claim 2, wherein said first network is one of a wide area network, and a wireless network.
 6. The method of claim 2, wherein said second network is one of a wide area network, a wireless network, and a local area network.
 7. The method of claim 2 wherein said first message further includes additional parameters in a body of said first message, and wherein said additional parameters are relevant to said execution of said application function, and wherein said additional parameters are expressed as alphanumeric text.
 8. The method of claim 1 wherein said first text-based user-to-user messaging protocol is different from said second text-based user-to-user messaging protocol.
 9. The method of claim 1, wherein said first text-based user-to-user messaging protocol and said second text-based user-to-user messaging protocol includes at least one of SMTP, SMS, MMS, IM, XMPP, web service, SOAP, WAP, HTTPS, or HTTP.
 10. The method of claim 1, further comprising authenticating in said proxy server a user associated with said first message origination address by sending an authentication message to said user at a message confirmation address and receiving confirmation from said user responsive to said authentication message.
 11. The method of claim 10 wherein said message confirmation address is different from said first message origination address.
 12. The method of claim 10, wherein said message confirmation address is the same as said first message origination address.
 13. The method of claim 1, wherein said first message is created on said client device with a form.
 14. The method of claim 13, wherein said form is one of an XForm, a HTML form, and a WML form.
 15. The method of claim 1, wherein said plurality of unique return addresses includes a temporary mailbox.
 16. The method of claim 1, wherein said plurality of unique return addresses represent paths through a menu tree.
 17. The method of claim 1, wherein said application server includes a graphical user interface, and wherein said proxy server is coupled to said application server through said graphical user interface.
 18. The method of claim 1, wherein said application server includes an API, and wherein said proxy server is coupled to said application server through said API.
 19. The method of claim 1, wherein said first text-based user-to-user messaging protocol is the same as said second text-based user-to-user messaging protocol.
 20. The method of claim 1, wherein a unique return address of the plurality of unique return addresses is encrypted.
 21. A proxy server for enabling a client device to remotely execute an application function on an application server, said client device being coupled to said proxy server, said proxy server being further coupled to said application server that executes said application function, said proxy server comprising: a processor; a memory: means for receiving at said proxy server from said client device a first message, wherein said first message includes a first message destination address and a first message origination address, and wherein said proxy server is a final destination of said first message, and wherein said first message includes a first human-readable input parameter; and wherein said first message conforms to a first text-based user-to-user messaging protocol; means for transmitting from said proxy server to said client device a first response, wherein said first response includes a plurality of unique return addresses for signaling respective particular changes in state for said client device, wherein said unique return addresses are unique for said client device; means for receiving at said proxy server from said client device a second message, wherein said second message is indicative of a user selection of one of said plurality of unique return addresses, and wherein said proxy server is a final destination of said second message, and wherein said second message pertains to a request to execute said application function, and wherein said second message includes a second human-readable input parameter; and wherein said second message conforms to a second text-based user-to-user messaging protocol; means for selecting in said proxy server said application server based on one or both of said first message and said second message; means for generating in said proxy server a third message utilizing one or both of said first message and said second message, wherein said third message is for use by said application server; and means for transmitting to said application server from said proxy server said third message, to cause said application server to execute said application function based on said third message.
 22. The proxy server of claim 21 wherein said client device is coupled to said proxy server via a first network, and said proxy server is coupled to said application server via a second network.
 23. The proxy server of claim 22, wherein said first network and said second network are the same.
 24. The proxy server of claim 22, wherein said first network and said second network are not the same.
 25. The proxy server of claim 22, wherein said second network is one of a wide area network, a wireless network, and a local area network.
 26. The proxy server of claim 22 wherein said first message further includes additional parameters in a body of said first message, and wherein said additional parameters are relevant to said execution of said application function, and wherein said additional parameters are expressed as alphanumeric text.
 27. The proxy server of claim 21, wherein said first network is one of a wide area network, and a wireless network.
 28. The proxy server of claim 21 wherein said first text-based user-to-user messaging protocol is different from said second text-based user-to-user messaging protocol.
 29. The proxy server of claim 21, wherein said first text-based user-to-user messaging protocol and said second text-based user-to-user messaging protocol includes at least one of SMTP, SMS, IM, web service, SOAP, HTTPS, or HTTP.
 30. The proxy server of claim 21, further comprising means for authenticating in said proxy server a user associated with said first message origination address by sending an authentication message to said user at a message confirmation address and receiving confirmation from said user responsive to said authentication message.
 31. The proxy server of claim 30 wherein said message confirmation address is different from said first message origination address.
 32. The proxy server of claim 30 wherein said message confirmation address is the same as said first message origination address.
 33. The proxy server of claim 21, wherein said application server includes a graphical user interface, and wherein said proxy server is coupled to said application server through said graphical user interface.
 34. The proxy server of claim 21, wherein said application server includes an API, and wherein said proxy server is coupled to said application server through said API.
 35. The proxy server of claim 21, wherein said first text-based user-to-user messaging protocol is the same as said second text-based user-to-user messaging protocol.
 36. The proxy server of claim 21, wherein a unique return address of the plurality of unique return addresses is encrypted.
 37. The proxy server of claim 21, wherein said plurality of unique return addresses includes a temporary mailbox. 